The desalter also helps to deal with other challenges including organic fouling and biofouling, without the requirement of extra chemicals.

By increasing the brine recovery from BWRO plants, the technology helps to reduce the environmental impact of brine.

According to the company, this technology will help boost water recovery in municipal and industrial applications such as mining sites, power stations and cooling towers.

IDE product line head and business development director Tomer Efrat said: “Reaching high recovery for BWRO systems has always been a challenge, which in many cases determined whether a project would be economically viable or not.

“MAXH2O is definitely breaking the recovery limits known in the industry today, thus providing many more opportunities for both new installations and retrofitting existing facilities.”

Initial pilots of MAXH2O technology on both current and new BWRO desalination plants have indicated that brine recovery can go up to 98%.

Due to the presence of soluble salts such as calcium carbonate, silica and calcium sulfate, BWRO and reuse plants are not able to maximise the potential of the BWRO plant and reaching the optimum RO osmotic pressure limit.

The presence of soluble salts is leading to scale formation in the system and on the RO membranes. Consequently, the recovery of BWRO plant is being restricted to around 80%.

The MAXH2O desalter technology makes use of a semi-batch RO concept along with an integrated salt precipitating unit to eliminate the recovery limitation caused as a result of water chemistry.

By making use of a semi-batch process, the flow through the membranes in the MAXH2O desalter is increased, which leads to high cross-flow velocities within the RO membrane feed brine spacer, thereby reducing the risk of scale formation.

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